DE2324059A1 - PRESSURE CONTROLLED DIRECTIONAL VALVE - Google Patents

Description

ALFEED TEVSS GMBH May 4, 1973

Prankfurt am Main

P 4181. ZL / white / c

L. Budecker -21 H. von Grünberg - 7

Pressure controlled directional valve

The invention relates to a pressure-controlled directional control valve which the Controls the flow rate of a pump to a circulating or accumulator hydraulic system, with a lower pressure for the circulating system than is required for the storage hydraulic system, and in which the storage hydraulic system has a towards the pump blocking check valve is constantly connected to the pump.

It is e.g. in motor vehicles with a circulation system for IT level regulation and an accumulator hydraulic system for brake pressure boosting required that the accumulator hydraulic system in each In this case, it is primarily supplied with pressure medium, i.e. that the reservoir is immediately refilled if it falls below a certain pressure level must be used so that the brake always remains operational. During the time of the filling up of the reservoir, the pressure medium supply the circulation system can be interrupted without endangering the vehicle.

Through the DT-AS 2 005 554 a part valve is known by which is the flow rate of a pump in a circulation and a storage hydraulic system is distributed. With this valve, the conveying flow is divided in a certain proportion, with the one part

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is fed to the circulation system and the other part of the Accumulator hydraulic system; otherwise it is diverted into the return. Since both systems are supplied with pressure medium at the same time with this valve, the pump must have corresponding capacity large. However, since the hydraulic accumulator system is only rarely operated and therefore only very little pressure medium is required, the flow rate allocated to it is sent to the return tank derived. This results in a very high power loss and the total Arrangement works with an extremely poor efficiency. In addition, the pump is due to the required oversizing expensive.

It would also be possible to control the flow via an electromagnetic 3/2 way valve, which is controlled by a pressure switch, to be routed into the desired system. However, it is with pressure-controlled Systems a detour and therefore too expensive to switch hydraulic paths using electrical energy. In addition, this detour results in a greatly increased susceptibility to failure.

The invention is based on the object of creating a directional control valve controlled by the accumulator pressure, through which the entire delivery flow the pump is fed to either the circulation or the hydraulic accumulator system, with the hydraulic accumulator system having priority pressure medium is to be supplied.

This object is achieved in that by means of a Shut-off element, the connection from the pump to the circulation system can be closed, with the shut-off element in Closing direction is biased, and that a space behind a pressure-exerting surface of the shut-off element opposite to the closing direction by means of a pressure medium connection with a small cross section a pressure medium connection of the pump is connected, and this space

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again depending on the pressure in the accumulator via a pilot valve can be connected to the return.

Another advantageous embodiment of the invention consists in that in the valve slide a further pressure medium connection from the space behind the pressure application area of the shut-off element to the return is provided, which is apparent depending on the pressure in this space.

It is also advantageous that the valve element of the pilot valve acted upon in the closing direction by the pressure in the accumulator and counter to the closing direction by resilient means with a negative characteristic is biased. The decrease in force of the resilient means can be increased by the flow of pressure medium.

The advantages achieved with the invention are in particular: that by using the directional control valve according to the invention two of each other independent hydraulic systems can be supplied with pressure medium by means of a pump, the capacity of this pump only needs to be designed for one system. This has the advantage of being a relatively small and therefore cheap pump to be able to use. It is also with the directional control valve according to the invention possible to primarily supply the more important hydraulic system with pressure medium. This increases the possibility of failure of the Hydraulic system, which directly serves the safety of the vehicle, almost impossible due to insufficient pressure medium supply. if the hydraulic storage system does not require any pressure medium, so the entire flow rate is fed to the circulation system and it occurs no loss of performance due to recirculation of part of the flow rate to the reservoir. Furthermore, the feed pump only has to counter the pressure in this system when the hydraulic accumulator system requires pressure medium the required higher pressure. Since the valve is fast switching,

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If necessary, the storage system is immediately supplied with pressure medium. Further advantages result from those shown in FIGS. 1 ″ to 5 Embodiments.

Show it

Figure 1 shows an embodiment of the directional control valve according to the invention in section, the connected elements are indicated schematically,

Figure 2 the characteristic curve of the resilient means of the pilot valve,

Figure 3 shows a further embodiment of the inventive Directional control valve,

Figure 4 shows an embodiment of the directional control valve according to the invention, in which the valve element of the pilot valve is operated by a compression spring that is operated by a permanent magnet is supported, is biased,

FIG. 5 shows the characteristic curve of the resilient means in the working area of the pilot valve.

A pump 1 is connected on the one hand via a line 27 to a storage container 10 and on the other hand via a line 25 to a connection 20 of a directional control valve 2 according to the invention. A line 26 connects the line 23 via a pressure relief valve 16 to the reservoir 10. A connection 21 of the directional control valve 2 is connected by a line 24 via a check valve 3 ^m i * blocking in the direction of the directional control valve 2 to an accumulator 4 of a hydraulic accumulator system. A connection 22 of the directional control valve 2 is connected to a line 25 which leads to a circulation system. A line 28 connects the section of the line 24 between the check valve 3 and the accumulator 4 with a connection 29 of a pilot valve 5.

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A space JO in the pilot valve 5 is connected to the storage container 10 via a connection 31 and a line 32. A piston 7, which is acted upon on the one hand by the control pressure from the connection 29, on the other hand is supported in the space JO on a valve slide 8, whereby it is guided axially displaceably tightly through a part 33 of the pilot valve 5. The valve slide 8 is pretensioned in the direction of the part 33 by a plate spring 6 in the space 30. The valve slide 8 is guided in a bore 35. An annular space 34 is connected to the space 30 via the control edge 12. A space 37 in front of an end face of the control slide 8 is connected to the rium 30 via a channel 36.

The space 34 is a space * 9 connected via a channel 3 ⁸ mi front of an end face of a shut-off element. 11 The shut-off element 11 is pretensioned in the direction of the space 9 by means of a spring I3, which is supported on the one hand in a recess 59 of the shut-off element 11 and on the other hand on a closure piece I7. The shut-off element 11 closes the pressure medium connection to the connection 22 by means of a sealing surface 40. An annular groove 4I of the shut-off element 11 is permanently connected to the connection 20. A tight pressure medium connection 15 leads from the annular groove 4I to the space 9. The displacement path of the shut-off element 11 is limited by a stop I4 on the closure piece 17.

The way the valve is punctured is as follows:

The pump 1 sucks pressure medium through the line 27 from the storage container 10 and conveys it through line 23 to connection 20 of the directional control valve 2. If the pressure level of the accumulator 4 is below the lower switching point, the shut-off element 11 is in the position shown. The pump now delivers through port 21

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and the line 24 via the check valve 3 into the reservoir 4. After the appropriate filling, the pressure of the accumulator 4 "rises to the upper switching point. This pressure is generated via the control line 28 passed to terminal 29 and applied there to the Piston 7 · The piston 7 now moves against the force of the disc spring 6 the control slide in the closing direction. This process happens suddenly due to the negative spring characteristic. Through the Displacement of the control slide 8, the connection of the space 34 to the tree 30 at the control edge 12 is interrupted.

The pressure medium flowing through the pressure medium passage 15 can no longer ^{escape through the channel 38 and} the space 34 into the space 30. A pressure thus builds up in space 9, which acts on the end face of the shut-off element 11 and moves it in the direction of the closure piece 17 against the force of the spring 13 up to the stop 14. This releases the connection from connection 20 to connection 22 and the pump can convey into the circulation system. Due to the higher pressure in the accumulator, the check valve closes 3 ODd thus preventing a backflow of the pressure medium.

If the pressure of the accumulator 4 now falls due to the consumption of pressure medium to the lower switching point, the plate spring 6 overcomes the force on the piston 7 and moves the control slide 8 back into the position shown. As a result, the pressure medium connection between the spaces 34 and 30 is released again. The pressure prevailing in space 9 can now be reduced via connection JB, space 34 »30, connection 5I through line 52 to the storage container. As a result, the shut-off element 11 is moved back into the position shown by the force of the spring 13. The connection from connection 20 to connection 22 is thus interrupted again and the pump can now only deliver into memory 4.

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The diagram in FIG. 2 shows the characteristic curve of the disc spring 6. The control pressure in bar, which acts on the piston 7 and is proportional to the spring force, is plotted on the ordinate, and the path f by which the spring is moved according to this pressure * is plotted on the abscissa. The switching points required for the selected application case P corresponds to 200 bar and P "corresponds to I50 bar with the associated spring deflections f .. and f are now entered. This results in the working stroke of δ f required for the pilot valve. * pressed together

In Figure 3, another possible embodiment of the Vegeventils according to the invention is shown. The same parts have been given the same reference numbers. The storage container 10 is connected to the pump 1 via a line 27. The pump 1 is connected to the connection 21 via a line 23. A conduit 24 connects the reservoir 4 via a check valve 3 ^m i 't of the line 23. A terminal 22 is connected via a line 25 with the tfmlaufanlage. The shutoff element 11 is movably guided in a bore 40. There is a spring I3 " which is supported on the one hand on the shut-off element 11 and on the other hand on the closure piece Λ ^ , preloaded in the closing direction. The size of the pressure medium connection 15 from a space 58 to a space 57 "which consists of notches in the circumference of the shut-off element 11 depends on the Position of the shut-off element 11 in relation to a control edge 54 · Her room 57 is in connection with the room 9. A passage 38 connects the room 9 with the room 30.

A control line 28 connects the line 24 to the terminal 29 of the pilot valve 5 The piston 7 of the pilot valve 5 is acted upon on the one hand by the accumulator pressure and on the other hand is based on a valve element 52, which by a Disk spring 6 is biased in the direction of part 33, from. The valve element 52 of the pilot valve 5 is a seat valve

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formed and closes a pressure medium passage 56 »which space 30 with a space 53 »in which the spring I3 is located. The room 53 is * again via the connection 3I "and · the line 32 · connected to the storage container 10.

A channel 67 connects when the shut-off element is in a certain position 11 room 9 with room 53

The way the valve is punctured is as follows:

In the position shown, the shut-off element 11 connects the pressure medium connections 21 and 22, as a result of which the pump 1 supplies the circulation system with pressure medium. If the pressure in the accumulator now falls below the lower switching point, the plate spring 6 moves the valve element 52 and the piston so that the pressure medium connection 56 between the spaces 30 and 53 is opened Pressure medium connection 38, space 30, pressure medium connection 56, space 53 ^to connection 31 to the reservoir through line 32. Now the spring I3 moves the shut-off element 11 in the direction of the plug 51, whereby the connection to connection 22 is interrupted 1 via the lines 23 the check valve 3 the line 24 into the memory 4

If the pressure in the storage tank has now increased to the upper switching point, then the piston 7 moves the valve element 52 against the force of the Disk spring 6 and closes the pressure medium passage 56. As a result can that flowing through the pressure medium passage 15 into the space 9 Pressure medium no longer flow off to the reservoir and a pressure builds up in space 9, which pushes the shut-off element 11 in the direction Sealing plug 17 moves. This means that the pressure medium

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access to port 22 is released again. The shut-off element.11 now moves in the opposite direction as a result of the increasing pressure in space 9 » the spring 15 further to the right, so will 'from a certain Maximum pressure in space 9 of the pressure medium passage 57 to space 55 at a control edge 59 is released. This will reduce the pressure in the room 9 depending on the hardness of the spring 15 to a maximum Pressure limited.

In the embodiment according to FIG. 4, the structure and the The mode of operation of the directional valve is exactly the same as in the exemplary embodiment in FIG. 5. Only in the gate control valve was the disc spring replaced by a compression spring 62 and a permanent magnet 60. The same parts have been given the same reference numbers here as well Mistake.

The piston 7 of the pilot valve 5 is "fc attached to a part 61, which is movably arranged in a space 65. The part 61 will against the closing direction of the valve element 52 by a Compression spring, which is supported on the one hand on part 61 and on the other hand on the housing of the pilot valve against the closing direction biased. A permanent magnet 60, which is fastened in a part 64 which is screwed into the housing 5 of the pilot control valve is, the part 61 pulls against the closing direction of the valve element 52 and thus supports the action of the spring 62.

Through the combination of the compression spring 62 and the permanent magnet 60, a negative characteristic curve is again achieved here, as a result of which the pilot control valve and thus the directional control valve are switched quickly is achieved.

In the diagram in FIG. 5, the section of the negative characteristic curve of the resilient means in the working stroke of the pilot valve is shown.

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If the return connection, for example the pressure medium orifice 56 in FIG. 3, is connected directly to the suction chamber of the pump , the force acting on the closing member through the resilient means is influenced by the suction of the pump according to the dashed line in FIG. This has the advantage that the upper switching point P ₁ and the lower switching point P »are further apart than would be possible with the resilient means alone.

In all the exemplary embodiments, the pump 1 is protected against excess pressure by a pressure limiting valve 16 which is connected to the line 25 via a line 26.

The invention is not restricted to the above embodiments and it is possible further options.

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Claims (7)

Claims 1., - Pressure- controlled directional control valve, which controls the flow of a pump -s on a circulation or a Spexcherhydraulikanlage, whereby a lower pressure is required for the circulation system than for the hydraulic accumulator system, and in which the hydraulic accumulator system has a blocking in the direction of the pump Check valve is permanently connected to the pump, characterized in that the connection from the pump (i) to the circulation system can be closed by means of a shut-off element (11), the shut-off element (11) being pretensioned in the closing direction by resilient means (13), and that a space (9) behind a pressure application surface of the shut-off element (11) against the closing direction by a pressure medium connection (15) of small cross-section is connected to a pressure medium connection (20) of the pump (i) and this space (9) is in turn dependent on the pressure in the Memory (4) can be connected to the return (32) via a pilot valve (5). 2. Directional valve according to claim 1 or one of the following, characterized in that the shut-off element (11) as Valve slide is formed. - 12 - 409848/0172 3. Directional valve according to claim 1 or one of the following, characterized in that in the shut-off element (11) a Pressure medium connection (57) from space (9) behind the pressure application area of the shut-off element (11) to the return (32) is provided, which depends on the bridge in this space (9) is evident. 4 · way valve according to claim 1 or one of the following, characterized ■ that the valve element (8, 52) of the Pilot valve (5) acted upon in the closing direction by the pressure in the accumulator (4) and against the closing direction "by resilient means (6, 62 - 60) with a negative characteristic is biased. 5. Directional valve according to claim 4t, characterized in that a plate spring (6) with a negative as resilient means Characteristic is provided. 6. Directional valve according to claim 4 »characterized in that that as a resilient means a helical spring in operative connection (60)
is provided with a permanent magnet whose characteristic is negative. 7. Directional valve according to claim 4 to 6, characterized in that that the return connection (56) of the pilot valve (5) is directly connected to the suction chamber of the pump (1). 409848/0172 ts Blank page